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Fiber- and microresonator-based parametric generation.
Phase conjugation, optical limiting, all-optical switching.
Lecture 20
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Four-wave mixing, one pump wave.Continued.
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Four-wave mixing (FWM), one pump wave
𝜔" 𝝎𝟏 𝜔%One strong wave 𝝎𝟏 creates two new waves 𝜔" & 𝜔%
in a 4-wave process 𝟐𝝎𝟏 = 𝝎𝟑 + 𝝎𝟒
𝜟𝒌 = 𝟐𝒌𝟏 − 𝒌𝟑 − 𝒌𝟒 + nonlinear SPM and XPM terms
k
ω
𝑘%
𝑘"
𝑘/
ω
𝑘%
𝑘"𝑘/
Dispersion of a fiber or a waveguide
k
dispersive phase matching
“zero group dispersion”
“normal dispersion”
k
ω
𝑘%
𝑘"𝑘/
“anomalous dispersion”
𝜔/ 𝜔/𝜔/
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Phase matching terms due to SPM and XPM
Example: fused silica: 𝑛1 = 3.2×10819 𝑚1/𝑊
𝛾>? =@ABCDEFF
= 1.3 x 10-3 (Wm)-1 3.3e-20 *1.2e15 /3e8 / 1e-10=λ=1.56 µm10 µm mode diam.
For chalcogenide(As2Se3) nano-wires: 𝛾>? ≈93 (Wm)-1
Thus, for strong pump field 𝝎𝟏 with power 𝑃, SPM term gives
∆𝜑 = 𝑘9Δ𝑛𝐿 =𝜔𝑐𝑛1𝐼𝐿 =
𝜔𝑐𝑛1
𝑃𝐴PQQ
𝐿 = 𝛾>?𝑃𝐿
𝛾>? =𝜔𝑛1𝑐𝐴PQQ
=2𝜋𝑛1𝜆𝐴PQQ
In guided wave optics, the nonlinearity is expressed with the factor 𝛾 [ in (Wm)-1 ]
∆𝜑 = 𝛾>?𝑃𝐿 à ∆𝑘 = 𝛾>?𝑃
For weak fields 𝝎𝟑 and 𝝎𝟒 , XPM terms give∆𝑛 = 𝑛1(𝐼/ + 2𝐼1)Recall formula (17.10a)
probe beam pump beam, co-polarized
𝑛1 =3𝜒 "
4𝑛91𝜖9𝑐- self phase modulation ceff.
For strong 𝝎𝟏 field, SPM term gives
∆𝜑 = 𝑘9Δ𝑛𝐿 =𝜔𝑐 𝑛1𝐼𝐿 =
𝜔𝑐 𝑛1
𝑃𝐴PQQ
𝐿 = 𝛾>?𝑃𝐿
One also needs to take into accound nonlinear phase related to SPM and XPM
∆𝑘 = 2𝛾>?𝑃 for both 𝜔" and 𝜔%
2(𝑘/ + 𝛾>?𝑃) = 𝑘" + 2𝛾>?𝑃 + 𝑘% + 2𝛾>?𝑃Hence phase matching condition becomes
2𝑘/ = 𝑘" +𝑘% +2𝛾>?𝑃
(20.1)
=fiber nonlinear parameter
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Four-wave mixing (FWM), one pump wave
g = "Z [
\CB]BAB[B^
@]@A@[@^≈ "Z [ BA
\C@A
𝛾 = | 𝐴/|1𝑔
From previous lecture, see (19.18)signal and idler intensities grow as:
𝐼3 = 𝐼30 𝑐𝑜𝑠h2(𝛾𝑧)
𝐼4 =𝜔%𝜔"
𝐼30 𝑠𝑖𝑛ℎ2(𝛾𝑧)
where
gain increment
Let us express the gain increment 𝛾 through power 𝑃 at 𝝎𝟏
𝑃3 = 𝑃30 𝑐𝑜𝑠h2(𝛾𝑧)
𝑃4 =𝜔%𝜔"
𝑃30 𝑠𝑖𝑛ℎ2(𝛾𝑧)à
𝛾 = | 𝐴/|1𝑔 = | 𝐴/|13𝜒 " 𝜔1
8𝑐𝑛1 =2𝐼𝜔𝑐𝜀9
3𝜒 " 𝜔1
8𝑐𝑛1 =3𝜒 " 𝜔4𝜀9𝑐1𝑛1
𝑃𝐴PQQ
=𝑛1𝜔𝑐𝐴PQQ
𝑃 = 𝛾>?𝑃recall: 𝐼 = BCij
1𝐴 1
𝑛1 =3𝜒 "
4𝑛91𝜖9𝑐
𝛾>?
( in m-1 )
Thus, phase matching condition is power dependent (unlike 𝜒 1 processes!)
2𝑘/ = 𝑘" +𝑘% +2𝛾>?𝑃 𝑃3 = 𝑃30𝑐𝑜𝑠h2(𝛾>?𝑃𝐿)
(20.2)
(20.3)
=fiber nonlinear parameter
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Degenerate four-wave mixing in a fiber
Generated radiation in the visible and mid-IR regions: 1064 nm à 673 nm + 2539 nm
Let us estimate the fiber NL parameter and 4-wave gain in this experiment
Gain = 𝑐𝑜𝑠h2(𝛾>?𝑃𝐿) = 𝑐𝑜𝑠h2(2e−3∗1e5∗1.4)=𝑐𝑜𝑠h2(280) à exp(560)
𝛾>?= 1q@ArDEFF
=2 x10-3 (Wm)-1
NL contribution to the k-vector sum à Δ𝑘st = 2𝛾>?𝑃 = 2∗2e−3∗1e5=400 m-1
(Linear mismatch Δ𝑘 in the biulk SiO2 would be larger : 8500 m-1)
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Four-wave mixing on a photonic chip
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Four-wave mixing on a photonic chip
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Kerr-nonlinearity induced optical parametric oscillation in a toroidal SiO2 microcavityD ≈ 50 µm
Signal /idler spectrum
Idler emission versus pump power. The differential conversion efficiency from pump to idler was 17% (and correspondingly 34% for pump to signal and idler).
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Optical phase conjugation
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Optical phase conjugation
It is possible, using nonlinear optical processes, to exactly reverse the propagation direction and phase variation of a beam of light.
The reversed beam is called a conjugate beam, and thus the technique is known as optical phase conjugation.
It is also called time reversal, wavefrontreversal.
Comparison of a phase-conjugate mirror with a conventional mirror.
With the phase-conjugate mirror the image is restored when passing back through an aberrating element
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Optical phase conjugation
PHASE-CONJUGATE MIRROR is able to compensate for distortions imposed on an image of a cat.
In both photographs the image was distorted by transmitting it through a piece of frosted glass. Reflection of the image back through the same piece of glass by an ordinary mirror yielded an unrecognizable image (top).
Reflection of the image back through the frosted glass by a phase-conjugate mirror, on the other hand, corrected the distorted image (bottom).
It did so because a phase-conjugate mirror produces a beam that propagates back through the distorting glass in a "time-reversed" sense: its trajectory retraces that of the original beam and thereby undoes the distortions.
phase-conjugate mirror
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Optical phase conjugation
Let us regard a degenerate four-wave mixing process is – all four interacting waves have the same frequency.
In this process, a lossless nonlinear medium with a third-order nonlinear susceptibility χ(3) is illuminated by two strong counterpropagating pump waves E1 and E2 and by a signal wave E3.
a new wave E4 is created that is the phase conjugate of E3.
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Optical phase conjugationTwo strong counterpropagating pump waves E1 and E2 at ω
In a 4-wave process 𝜔 = 𝜔 − 𝜔 + 𝜔
ℰ(𝑡) = /1 ( 𝐸/𝑒
yB]z + 𝐸1𝑒yBAz + 𝐸"𝑒yB[z + 𝐸%𝑒yB^z + 𝑐. 𝑐.)
𝒫st(𝑡) =/\𝜖9𝜒
" ( 𝐸/𝑒yB]z + 𝐸1𝑒yBAz + 𝐸"𝑒yB[z + 𝐸%𝑒yB^z + 𝑐. 𝑐.)3
total field
total NL polariz.
𝒫st 𝑡 |𝜔 =/\𝜖9𝜒
" ( 6𝐸/𝐸1𝐸"∗𝑒yBz 8y(𝒌𝟏|𝒌𝟐8𝒌𝟑)𝒓 + 𝑐. 𝑐.)="%𝜖9𝜒
" ( 𝐸/𝐸1𝐸"∗𝑒yBz|y𝒌𝟑𝒓 + 𝑐. 𝑐. )
Signal wave E3 at ω
The nonlinear polarization at ω produced within the medium by all three input waveswill be:
𝒌𝟏 𝒌𝟐𝐸/ = 𝐸/𝑒yBz8y𝒌𝟏𝒓
𝐸1 = 𝐸1𝑒yBz8y𝒌𝟐𝒓
𝒌𝟏+𝒌𝟐=0
since 𝒌𝟏+𝒌𝟐=0
We see that this contribution to the nonlinear polarization has a spatial dependence that allows it to act as a phase-matched source term for a conjugate wave E4 having wavevector −k3, and thus we see that the wavevectors of the signal and conjugate waves are related by k3 = −k4.
𝑘"
𝒌𝟏 𝒌𝟐
𝑘"𝑘%
𝐸" = 𝐸1𝑒yBz8y𝒌𝟑𝒓
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Optical phase conjugation
𝑃% =32 𝜖9𝜒
" ( 𝐸/𝐸1𝐸"∗)àFourier components for 𝑃st
Now plug into SVEA equations - get coupled equations:
𝑑𝐸%𝑑𝑧 =
𝑖𝜔2𝑛𝑐𝜖9
32 𝜖9𝜒
" ( 𝐸/𝐸1𝐸"∗) = 𝑖𝛾𝐸"∗
Since the process is phase matched, the reflected conjugate field E4 will be amplified in –z direction (𝐸"∗ serving as a seed), and its power can even exceed the incoming power E3, that is the reflectivity of a phase conjugate mirror can be >100%
𝐸" = 𝐸1𝑒yBz8y𝒌𝟑𝒓
𝐸% = 𝐸1𝑒yBz|y𝒌𝟑𝒓𝑃" =
32 𝜖9𝜒
" ( 𝐸/𝐸1𝐸%∗)
𝑑𝐸"𝑑𝑧 =−
𝑖𝜔2𝑛𝑐𝜖9
32 𝜖9𝜒
" ( 𝐸/𝐸1𝐸%∗) = −𝑖𝛾𝐸%∗
𝐸% grows in the opposite direction: -z
0 L
𝐸"𝐸%
𝛾 =34𝜔𝜒 "
𝑛𝑐 𝐸/𝐸1 𝐸"9
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Optical phase conjugation, time reversed wavefront
𝐸% ~ 𝐸"∗𝑒yBz|y𝒌𝟑𝒓 + 𝑐. 𝑐.
= 𝐸"(𝒓)𝑒8yBz8y𝒌𝟑𝒓 + 𝑐. 𝑐.
Compare to 𝐸"~ 𝐸"(𝒓)𝑒yBz8y𝒌𝟑𝒓 + 𝑐. 𝑐.
- time is reversed: t → -t
The generated wavefront exactly replicates the incident wavefront but propagates in the opposite direction. For this reason, optical phase conjugation is sometimes referred to as the generation of a time reversed wavefront
𝒓
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Optical phase conjugation, one more interpretation
The object beam E3 is a spherical wave and the other two are reference (strong) beams. The beam E4, an output beam, is the desired phase conjugate of the object beam.
The interaction of the object beam with one of the reference beams E1 (blue) produces an interference pattern in the medium. The second reference beam E2 (red) is reflected by the interference pattern. Since the second reference beam comes from a direction opposite to that of the first reference beam, the reflected beam E4 is the phase conjugate of the object beam. In reality all the processes occur simultaneously.
E3E4
E1 E2
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Optical phase conjugation
First in, first out (ordinary mirror) Last in, first out (conjugate mirror)
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Optical power limiting
In a material with a strong nonlinear effect (e.g. two-photon absorption), the absorption of light increases with intensity such that beyond a certain input intensity the output intensity approaches a constant value. Such a material can be used to limit the amount of optical power entering a system. This can be used to protect expensive or sensitive equipment such as sensors, can be used in protective goggles, or can be used to control noise in laser beams.
ExperimentTheory
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All-optical switching
All-optical switch in the form of a Mach–Zehnder interferometer containing a nonlinear element.
nonlinear element
Nonlinear phase shift φNL needs to be π radiansto switch from one state to another
~ intensity
On-a-chip version
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